Specimen radiography with tomosynthesis in a cabinet with geometric magnification

ABSTRACT

The aspects of the present disclosure are directed to a method and system for producing tomosynthesis images of a breast specimen with the capability of attaining images with geometric magnification. In one embodiment, an x-ray source delivers x-rays through a specimen of excised tissue and forms an image at a digital x-ray detector with the resultant image enlarging as the specimen is moved closer to the x-ray source. Multiple x-ray images are taken as the x-ray source moves relative to the stationary breast specimen. The source may travel substantially along a path while the detector remains stationary throughout and the source remains substantially equidistant from the specimen platform. The set of x-ray image data taken at the different points are combined to form a tomosynthesis image that can be viewed in different formats, alone or as an adjunct to conventional specimen radiography.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to and the benefit of U.S. patent application Ser. No. 15/696,341, filed Sep. 6, 2017, currently pending, which, in turn, claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 62/384,303 filed Sep. 7, 2016, the disclosures of which are incorporated herein by reference in their entirety.

BACKGROUND Field of the Present Disclosure

The aspects of the disclosed embodiments are directed to the field of cabinet x-ray imaging of excised human tissue, and more specifically, to a system and method for obtaining and processing cabinet x-ray image data for tomosynthesis reconstruction allowing for a three-dimensional image of the specimen with the capability of attaining images of the specimen with geometric magnification and the purpose of such devices, as described in U.S. Pat. No. 9,138,193 Lowe, et. al., entitled “Specimen Radiography with Tomosynthesis in a Cabinet,” the disclosure of which is hereby incorporated by reference in its entirely in the present application.

Description of the Related Art

Imaging of a patient's tissue has become a common screening tool and/or diagnostic aid in modern medicine. Breast cancer remains an important threat to women's health and is the most common cancer among women today. One strategy for dealing with breast cancer is early detection of the cancer so that it may be treated prior to the cancer metastasizing throughout the body. This causes an increase in the number of surgical procedures performed involving excision of cancerous tissue or calcifications, such as ductal carcinoma in situ (DCIS).

The excision of Ductal carcinoma in situ (DCIS) is a challenging task. In order to assure that the complete DCIS lump including a cancer-free margin has been excised, the following steps may be undertaken. A pre-operational planning based on mammograms is performed carefully in order to assess the size and the location of the lump. The location of the lump is marked utilizing guide wires/markers. During the lumpectomy, the excised tissue is examined using x-ray imaging in order to assess whether its margin is cancer-free. If it is found that the excised specimen has an insufficient margin of cancer-free tissue, the surgeon removes more tissue.

Currently, x-ray images obtained are only available in two-dimensional mode and as such orthogonal views of the sample must be obtained by physically rotating the specimen to verify the margins. The breast surgeon relies on the radiogram to verify removal of the complete lump. If necessary, the breast surgeon may have to identify additional breast tissue that must be excised to ensure a clear margin. This can be an error prone and time consuming task that is performed under significant time pressure whilst the anesthetized patient is still lying on the operating table.

In typical x-ray imaging, a patient's breast sample is immobilized and contained in a specimen container. The sample is placed between an x-ray source and a digital imaging device (detector) to create a two-dimensional radiographic image of the sample. To ensure that margins are attained, at least 2 orthogonal images must be taken of the sample (90 degrees apart). The problem that arises with the above scenario is that the tissue, being somewhat fluid, may displace when it is imaged in either position, which may cause a false measurement to the breast surgeon. It would be advantageous to be able to image the sample from a greater number of different positions of the source and receptor relative to the sample while maintaining the sample stationary or in a fixed position.

Digital tomosynthesis combines digital image capture and processing with simple tube/detector motion as used in conventional radiographic tomography. Although there are some similarities to CT, it is a separate technique. In CT, the source/detector makes a complete 360-degree rotation about the subject obtaining a complete set of data from which images may be reconstructed. In digital tomosynthesis, a small change of flux created by only a small rotation angle with a small number of exposures are used. This set of data can be digitally processed to yield images similar to conventional tomography with a limited depth of field. However, because the image processing is digital, a series of slices at different depths and with different thicknesses can be reconstructed from the same acquisition, saving time.

Image data taken at the different imaging positions can be processed to generate tomosynthetic images of selected slices of the sample. The images can be of thin slices, essentially planar sections through the specimen, as in CT slices. Alternatively they can be varying thickness.

The isocenter of the image acquisition geometry is located below the sample, on the surface of the detector. The phase shifts created as a result of this arrangement are compensated for, while processing the resultant dataset. The tomosynthetic images are then generated from the generated data set.

There may be cases where magnification of the specimen should be obtained to provide a better image or visualization of the anomalies present. Digital magnification can distort and/or pixelate an image at an “×” magnification whereas a geometric magnification would provide a magnification of an “×” power without any distortion of the sample.

It is believed that no cabinet specimen tomosynthesis systems utilizing geometric magnification are commercially available currently for clinical use in specimen imaging, and that improvements in x-ray imaging and tomosynthesis are a desired goal. Accordingly, it is believed that there is a need for improved and practical tomosynthesis of breast specimens with the capability of geometric magnification

It would be advantageous to have a cabinet x-ray system for specimen imaging that could create, via digital tomosynthesis, a three-dimensional image for the breast surgeon to ensure that a proper margin around the diseased tissue has been excised in an expedient manner.

To address this, in one aspect of the present disclosure include a sample tray holding the specimen may be elevated in the sample chamber above the detector to allow for a geometric magnification of the specimen imaged and to create images which would compensate and/or delete digital distortion.

SUMMARY

In one embodiment, a cabinet x-ray system for of obtaining geometric magnifying specimen x-ray images, projection x-ray images, and reconstructed tomosynthetic x-ray images of the specimen is provided. The system includes a moveable cabinet defining a walled enclosure surrounding an interior chamber and a door configured to cover the interior chamber; an x-ray source, a flat panel digital x-ray detector, a specimen platform including a magnification tray that is positioned at a distance above the flat panel digital x-ray detector to facilitate geometric magnification imaging of the specimen in the cabinet and a motion control mechanism configured for moving the x-ray source to or along a plurality of positions within the interior chamber relative to the specimen disposed on the specimen platform; and a controller. The controller is configured to selectively energize the x-ray source to emit x-rays through the specimen to the flat panel digital x-ray detector at selected positions of the x-ray source relative to the specimen such that the isocenter of the emitted x-rays at the selected positions is located at the flat panel digital x-ray detector surface, control the flat panel digital x-ray detector to collect projection x-ray images of the specimen when the x-ray source is energized at the selected positions, wherein one of the projection x-ray images is a two-dimensional x-ray image taken at standard imaging angle of about 0°; create a tomosynthetic x-ray image reconstructed from a collection of projection x-ray images, process the collection of the projection x-ray images in the controller into one or more reconstructed tomosynthetic x-ray images representing a volume of the specimen and relating to one or more image planes that are selectively the same or different from that of the two-dimensional x-ray image and selectively display the two-dimensional x-ray image and the one or more reconstructed tomosynthetic x-ray images.

In another embodiment, a method for obtaining x-ray images of a specimen in a cabinet x-ray system, processing and displaying a two-dimensional x-ray specimen radiography image and projection x-ray images of the specimen is provided, wherein the cabinet x-ray system includes a moveable cabinet defining a walled enclosure surrounding an interior chamber and a door configured to cover the interior chamber; an x-ray source, a flat panel digital x-ray detector, a specimen platform including a magnification tray that is positioned at a distance above the flat panel digital x-ray detector to facilitate geometric magnification imaging of the specimen, and a motion control mechanism configured for moving the x-ray source to or along a plurality of positions within the interior chamber relative to the specimen disposed on the specimen platform; and a controller configured to selectively energize the x-ray source to emit x-rays through the specimen to the flat panel digital x-ray detector at selected positions of the x-ray source relative to the specimen. The method includes controlling the flat panel digital x-ray detector to collect projection x-ray images of the specimen when the x-ray source is energized at the selected positions such that the isocenter of the emitted x-rays at the selected positions is located at the detector surface, wherein one of the projection x-ray images is a two-dimensional x-ray image taken at standard imaging angle of about 0°; creating a tomosynthetic x-ray image reconstructed from a collection of projection x-ray images; processing the collection of the projection x-ray images in the controller into one or more reconstructed tomosynthetic x-ray images representing a volume of the specimen and relating to one or more image planes that are selectively the same or different from that of the two-dimensional x-ray image; and selectively displaying the two-dimensional x-ray image and the one or more reconstructed tomosynthetic x-ray images.

In yet another embodiment, a cabinet x-ray system for of obtaining x-ray images, projection x-ray images, and reconstructed tomosynthetic x-ray images of a specimen is provided. The system Includes a cabinet defining an interior chamber, an x-ray source, an x-ray detector, a specimen platform, a motion control mechanism and a controller. The specimen platform includes a magnification tray that is positioned at a distance above the flat panel digital x-ray detector to facilitate geometric magnification imaging of the specimen in the cabinet. The motion control mechanism is configured for moving the x-ray source to or along a plurality of positions within the interior chamber relative to the specimen disposed on the specimen platform. The controller is configured to selectively energize the x-ray source to emit x-rays through the specimen to the x-ray detector at selected positions of the x-ray source relative to the specimen such that the isocenter of the emitted x-rays at the selected positions is located at a surface of the x-ray detector; control the x-ray detector to collect projection x-ray images of the specimen when the x-ray source is energized at the selected positions, wherein one of the projection x-ray images is a two-dimensional x-ray image taken at standard imaging angle of approximately 0°; create a tomosynthetic x-ray image reconstructed from a collection of projection x-ray images; process the collection of the projection x-ray images in the controller into one or more reconstructed tomosynthetic x-ray images representing a volume of the specimen and relating to one or more image planes that are selectively the same or different from that of the two-dimensional x-ray image; and selectively display the two-dimensional x-ray image and the one or more reconstructed tomosynthetic x-ray images.

In still another embodiment, a method for obtaining x-ray images of a specimen in a cabinet x-ray system, processing and displaying a two-dimensional x-ray image and projection x-ray images of the specimen is provided. The cabinet x-ray system includes a cabinet defining an interior chamber; an x-ray source, an x-ray detector, a specimen platform includes a magnification tray that is positioned at a distance above the flat panel digital x-ray detector to facilitate geometric magnification imaging of the specimen, and a motion control mechanism configured for moving the x-ray source to or along a plurality of positions within the interior chamber relative to the specimen disposed on the specimen platform; and a controller configured to selectively energize the x-ray source to emit x-rays through the specimen to the x-ray detector at selected positions of the x-ray source relative to the specimen. The method comprises includes controlling the x-ray detector to collect projection x-ray images of the specimen when the x-ray source is energized at the selected positions such that the isocenter of the emitted x-rays at the selected positions is located at a surface of the x-ray detector, wherein one of the projection x-ray images is a two-dimensional x-ray image taken at standard imaging angle of approximately 0°; creating a tomosynthetic x-ray image reconstructed from a collection of projection x-ray images; processing the collection of the projection x-ray images in the controller into one or more reconstructed tomosynthetic x-ray images representing a volume of the specimen and relating to one or more image planes that are selectively the same or different from that of the two-dimensional x-ray image; and selectively displaying the two-dimensional x-ray image and the one or more reconstructed tomosynthetic x-ray images.

As described herein, the exemplary embodiments overcome one or more of the above or other disadvantages known in the art. In one embodiment, the aspects of the present disclosure are directed to a method and system for obtaining breast specimen x-ray images, projection tomosynthesis x-ray images, and reconstructed tomosynthesis x-ray images of a patient's breast specimen (also referred to herein as a “sample”) and or performing digital tomosynthesis on an object. In one embodiment, the method and system includes an x-ray source, a flat panel digital x-ray detector, a specimen platform or container and a motion control mechanism configured for moving the source relative to the specimen (collectively referred to herein as the “unit”). The x-ray source is selectively energized to emit x-rays through the sample to the detector at selected positions of the source relative to the sample. The detector is controlled to collect projection x-ray images of the sample when the source is energized at the selected positions. One of the projection images is a two-dimensional image taken at standard imaging angle of 0°, and a tomosynthetic image reconstructed from a collection of tomosynthesis projection images is created.

In accordance with the aspects of the disclosed embodiments, the x-ray source moves around the stationary sample, typically, but not necessarily, in an arc. While the detector may rotate, in accordance with one aspect of the present disclosure, the detector remains stationary to maintain an equidistant center point. The x-ray data taken at each of a number of positions of the source relative to the sample is processed to form images, where two or more of the differing imaging positions are utilized to form a digital tomosynthesis image.

The specimen container/sample may be situated on a tray located directly above the detector to attain a 1:1 imaging as well as be able to be elevated on the tray to a multitude of elevations above the detector to create images with geometric magnification. The collection of the tomosynthesis projection images is processed, typically using a computing device or other processor, into one or more reconstructed images representing a volume of the sample and relating to one or more image planes that are selectively the same or different from that of the 2-D image. The 2-D image and the reconstructed tomosynthesis images are selectively displayed.

This above allows the clinician verification via a display of either a three-dimensional or slice/multiplanar view of the sample that margins have been attained by the surgeon.

In a further aspect, the disclosed embodiments are directed to method and system for selectively using the same x-ray equipment to take, process and display a 2-D specimen radiography image and projection tomosynthesis images. In one embodiment, this includes an x-ray source, a flat panel digital x-ray detector, and a specimen platform or container and a motion control mechanism configured for moving the source relative to the specimen (collectively referred to herein as the “unit”). The x-ray source is selectively energized to emit x-rays through the sample or specimen to the detector at selected positions of the source relative of the sample. The detector is controlled to collect projections x-ray images of the sample when the source is energized at the selected positions. One of the projection images is a two-dimensional image taken at standard imaging angle of 0° and a tomosynthetic image reconstructed from a collection of projection images is created.

The collection of the tomosynthesis projections images is processed by a computer or other processor into one or more reconstructed images representing a volume of the sample and relating to one or more image planes that are selectively the same or different from that of the 2-D specimen image. The 2-D specimen image and the reconstructed tomosynthesis images are selectively displayed.

The above aspects of the disclosed embodiments overcome the deficiencies of the prior art by advantageously allowing the operator to be able to view the sample in a three-dimensional mode and take varying slices to ensure that the surgeon has attained a correct margin in an expedient manner without having to manipulate the excised sample.

These and other aspects and advantages of the exemplary embodiments will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed solely for purposes of illustration and not as a definition of the limits of the invention, for which reference should be made to the appended claims. Moreover, the drawings are not necessarily drawn to scale and that, unless otherwise indicated, they are merely intended to conceptually illustrate the structures and procedures described herein. In addition, any suitable size, shape or type of elements or materials could be used.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1—Schematically illustrates a front view of an X-ray source, a specimen/sample, and a digital detector, where the X-ray source moves relative to the specimen for imaging the specimen at different angles, in one embodiment of a system incorporating aspects of the present disclosure.

FIG. 2—Schematically illustrates an exemplary orientation of the X-ray source, specimen, and digital detector as viewed when the door of the cabinet is open, in one embodiment of a system incorporating aspects of the present disclosure.

FIG. 3—Displays an exemplary workflow/flowchart of an aspect of the disclosed embodiments.

FIG. 4—Displays an example of an X-ray Cabinet System incorporating aspects of the present disclosure.

FIG. 5—Displays the sample chamber of the embodiment of FIG. 4 with the swing arm and a detector.

FIG. 6—Displays the lateral view of the X-ray source of the embodiment of FIG. 4 mounted to the top of the swing arm.

FIGS. 7A, 7B and 7C—Displays the results of the imaging of an apple at multiple depth cuts after tomosynthesis reconstruction in a cabinet X-ray system incorporating aspects of the present disclosure.

FIG. 8—Displays FIG. 2 but with the sample geometrically magnified on a raised sample tray as well as the magnification shelfs brackets in one embodiment of a system incorporating aspects of the present disclosure .

FIG. 9—Displays FIG. 1 but with the sample geometrically magnified on a raised sample tray in one embodiment of a system incorporating aspects of the present disclosure.

FIGS. 10A, 10B, and 10C—Display examples and theories of x-ray geometric magnification

DETAILED DESCRIPTION

The systems and methods of the disclosed embodiments address the needs of the art by providing tomosynthesis apparatus and techniques for imaging breast specimens that overcome the shortfall of the data received from two-dimensional imaging systems. The aspects of the disclosed embodiments enable the use of tomosynthesis to efficiently provide accurate three-dimensional imaging of a specimen in which overlapping images having differing attenuation characteristics by applying a three-dimensional reconstruction algorithm all in an x-ray cabinet with the option of providing geometric magnification of the specimen.

As used herein, the term “computer,” “computer system” or “processor” refers to any suitable device operable to accept input, process the input according to predefined rules, and produce output, including, for example, a server, workstation, personal computer, network computer, wireless telephone, personal digital assistant, one or more microprocessors within these or other devices, or any other suitable processing device with accessible memory.

The term “computer program” or “software” refers to any non-transitory machine readable instructions, program or library of routines capable of executing on a computer or computer system including computer readable program code.

Specimen Tomography is a three-dimensional specimen imaging system. It involves acquiring images of a sample at multiple viewpoints, typically over an arc or linear path. The three-dimensional image is constructed by the reconstruction of the multiple image data set. One embodiment of a system incorporating aspects of the present disclosure is illustrated in FIG. 1. The system is totally enclosed or housed in an X-ray cabinet 22. The aspects of the present disclosure include arc or linear travel of the x-ray source (10) over about a 20° to about a 50° arc, preferably about 30°, more preferably about 20°. The movement can be clockwise or counter clockwise along a path, which includes for example, one or more, or a combination thereof, of the following exemplary ranges: between approximately 350° (reference 12) to 0° (reference 14) to 10° (reference 16) or between approximately 340° (reference 12) to 0° (reference 14) to 20° (reference 16) or between approximately 335° (reference 12) to 0° (reference 14) to 25° (reference 16). The ranges recited herein are intended to be approximate and inclusive of start and endpoints. The detector 20 is stationary as is the sample 18 and is an x-ray detector and can include, for example, a flat panel x-ray detector, a flat panel digital x-ray detector. The reference “C” at each of the positions 12, 14, 16 of the X-ray source 10 in FIG. 1 refers to the point source of the X-ray beam. The reference “M” refers to the spread or fan of the X-ray beam.

In operation, source 10 is energized to emit an x-ray beam throughout its travel. The x-ray beam travels through the sample 18 to the detector 16 and the multiple images collected at varying angles are stored and then utilized for the tomosynthesis reconstruction. With the sample 18, also referred to as the “object” or “imaging object”, sitting on the detector 16 a 1:1 geometric magnification image is attained.

Different embodiments can utilize different ranges of motion of one or more of the source 10 and detector 20 as well as changing the angularity of one or both. The inventive aspects of the present disclosure differ from prior systems in that either both the detector and source move and/or the isocenter is above the sample and not at the detector surface. In accordance with the aspects of the present disclosure, in one embodiment, the source 10 may be configured to move or rotate, as is described herein, while the detector 20 is configured to remain stationary or in a fixed position.

Detector 20 and associated electronics generate image data in digital form for each pixel at each of the angular positions of source 10 and translations positions of the detector 20 relative to the sample 18. While only three positions are illustrated in FIG. 1, in practice more images are taken at differing angles, i.e. approximately every 1° of rotation or motion of source 10.

In operation, X-ray source 10 is energized to emit an X-ray beam, generally throughout its travel along one or more of the paths or positions described above. The X-ray beam travels through the sample 18 to the detector 20 and the multiple images collected at varying angles are stored and then utilized for the tomosynthesis reconstruction. The X-ray source 10 may range from about 0 kVp to about 90 kVp, preferably a 50 kVp 1000 μa X-ray source.

Different embodiments of the present disclosure can utilize different ranges of motion of one or more of the X-ray source 10 and detector 20 as well as changing the angularity of one or both. The inventive aspects of the present disclosure differ from the prior art in that in prior art systems either the detector and X-ray source 10 and/or the isocenter is above the sample and not at the detector surface. In accordance with the aspects of the present disclosure, in one embodiment, the X-ray source 10 is configured to move, as is described herein, while the detector 20 is configured to remain stationary or in a fixed position.

The detector 20 and associated electronics generate image data in digital form for each pixel at each of the angular positions 12, 14, 16 of X-ray source 10 and translation positions of the detector 20 relative to the sample 18. While only three positions 12, 14, 16 are illustrated in FIG. 1, in practice more images are taken at differing angles. For example, in one embodiment, images can be taken at approximately every 1° of rotation or motion of source 10.

FIG. 2 schematically illustrates one embodiment of the orientation of the X-ray source 10 as seen when the door 24 is opened and the X-ray source 10 is locate at approximately 0°, reference point 14 in this example, within the X-ray cabinet 22. In this embodiment, the motion of the X-ray source 10 can generally occur from the back to the front of the X-ray cabinet 22 with the detector 20 oriented, or otherwise disposed, at the base 26 of the X-ray cabinet 22, within the X-ray cabinet chamber 28. In one embodiment, the detector 20 is suitably coupled to the base 26 of the X-ray cabinet 22. The X-ray spread in this example can be from about 0 kVp to about 50 kVp with the system preferably utilizing an AEC (Automatic Exposure Control) to ascertain the optimal setting to image the object or sample 18 being examined.

In one embodiment, the detector 20, X-ray source 10, and the swing arm 60 (FIG. 5) servo mechanism are controlled via a combination of one or more of software and hardware, such as non-transitory machine readable instructions stored in a memory that are executable by one or more processors. On example of such a configuration can include controller cards of a computer 470 (FIG. 4), such as a MS Windows based computer. In one embodiment, non-transitory machine readable instructions being executed by one or more processors of the computer 470 is utilized to compile data received from the detector 20 and present resulting images to a suitable display or monitor 472 (FIG. 4) at each imaging position, such as positions 12, 14 and 16 shown in FIG. 1, the detector 20 generates the respective digital values for the pixels in a two-dimensional array. The size of detector 20 may range, for example, from about 5.08 centimeters by 5.08 centimeters to about 40.64 centimeters by 40.64 centimeters, preferably about 12.7 centimeters by 15.24 centimeters. In one example, detector 20 has a rectangular array of approximately 1536×1944 pixels with a pixel size of 74.8 micrometers. The image dataset attained at each respective position may be processed either at the full spatial resolution of detector 20 or at a lower spatial resolution by overlapping or binning a specified number of pixels in a single combined pixel value.

For example, if we bin at a 2×2 ratio, then there would be an effective spatial resolution of approximately 149.6 micrometers. This binning may be achieved within the original programming of the detector 20 or within the computer 470 providing the tomosynthetic compilation and image.

FIG. 3 illustrates one embodiment of an exemplary workflow from initiating 302 the system 100 through imaging, reconstruction and display 324 of data images collected of the sample 18.

As will be generally understood, the system exemplified in FIG. 1, for example, is initiated 302, the X-ray cabinet door 24 opened 304, and the sample 18 placed into 306 the X-ray cabinet chamber 28. As shown in FIG. 2, for example, the sample 18 is positioned on the detector 20 in a suitable manner. The door 24 is closed 308.

The data and information regarding the sample 18, including any other suitable information or settings relevant to the imaging process and procedure, is entered 310 into the computer 470. The scan is initiated 312. The system 100 will take 314 scout or 2-D images at Top Dead Center, which for purposes of this example is position 14 of FIGS. 1 and 2. The X-ray source 10 can then be moved to other positions, such as positions 12 and 16, and the detector 20 can be used to capture 316 images at various increments along the travel path of the X-ray source 10, such as about every 1 degree.

The captured images are stored 318 and digital tomosynthesis is performed 320. The tomosynthesis image is then displayed 324.

FIG. 4 shows one embodiment of an X-ray Cabinet System 400 incorporating aspects of the present disclosure. In this embodiment, the X-ray Cabinet System 400 is mounted on wheels 458 to allow easy portability. In alternate embodiments, the X-ray Cabinet System 400 can be mounted on any suitable base or transport mechanism. The cabinet 422 in this example, similar to the exemplary X-ray cabinet 22 of FIG. 1, is constructed of a suitable material such as steel. In one embodiment, the cabinet 422 comprises painted steel defining a walled enclosure with an opening or cabinet chamber 428. Within the cabinet chamber 428, behind door 424, resides an interior space forming a sample chamber 444, which in this example is constructed of stainless steel. Access to the sample chamber 444 is via an opening 446. In one embodiment, the opening 446 of the sample chamber 444 has a suitable door or cover, such as a moveable cover 448. In one embodiment, the moveable cover 448 comprises a door which has a window of leaded glass.

Between the outer wall 421 of cabinet 422 and the sample chamber 444 are sheets of lead 452 that serve as shielding to reduce radiation leakage emitted from the X-ray source 10. In the example of FIG. 4, the X-ray source 10 is located in the upper part 456 of the cabinet 422, in the source enclosure 468. The detector 20 is housed in the detector enclosure 460 at an approximate midpoint 462 of the cabinet 422.

In one embodiment, a controller or computer 470 controls the collection of data from the detector 20, controls the swing arm 60 shown in FIGS. 5 & 6, and X-ray source 10. A monitor 472 displays the compiled data and can, for example, be mounted on an articulating arm 474 that is attached to the cabinet 422. The computer 470 receives commands and other input information entered by the operator via a user interface 476, such as a keyboard and mouse for example. In one embodiment, the computer 470 can comprise a touch screen or near touch screen device. Although the aspects of the disclosed embodiments will generally be described with respect to a computer 470, it will be understood that the computer 470 can comprise any suitable controller or computing device. Such computing devices can include, but are not limited to, laptop computers, mini computers, tablets and pad devices.

The computer 470 can be configured to communicate with the components of the X-ray cabinet system 400 in any suitable manner, including hardwired and wireless communication. In one embodiment, the computer 470 can be configured to communicate over a network, such as a Local Area Network or the Internet.

FIG. 5 shows a front interior view and FIG. 6 shows a lateral interior view of the sample chamber of imaging unit cabinet of FIG. 4. In this embodiment, a sample 18 is placed or otherwise disposed onto the detector 20. Using the computer 470 shown in FIG. 4, the operator enters in the parameters for the scan via the user interface 476, which can be displayed on the monitor 472. As used herein, the term “display” or “monitor” means any type of device adapted to display information, including without limitation CRTs, LCDs, TFTs, plasma displays, LEDs, and fluorescent devices. The computer 470 then sends the appropriate commands to the X-ray source 10 and detector 20 to activate image collection while the swing arm 60 is moving along a path or arc from position 14 to 12 to 16 (which are shown in FIGS. 1 and 5) or vice versa as described, which in this embodiment are at 345°, 0°, and 15° respectively with 0° at top dead center. At the end of the travel of the swing arm 60 at either position 12 or 16, the computer 470 issues the command to the X-ray source 10 and the detector 20 to cease operating. The individual 2-dimensional (2-D) images which were collected, in this example at 1° increments, are then tabulated in the computer 470 to create the tomosynthetic images. In one embodiment, the operator may select which images they wish via the user interface 476 as they are being displayed on the monitor 472. In one embodiment, the devices and components of the X-ray cabinet system 400 are suitably communicatively coupled together, including one or more of hard wire connections or wireless connections using a suitable wireless connection and communication transmission protocol, as will generally be understood. The X-ray cabinet system 400 can also be configured to transfer images via USB, CD-ROM, or WIFI.

The dynamic imaging software of the disclosed embodiments reconstructs three-dimensional images (tomosynthesis) from two-dimensional projection images in real-time and on-demand. The software offers the ability to examine any slice depth, tilt the reconstruction plane for multiplanar views and gives higher resolution magnifications. FIGS. 7A, 7B, and 7C illustrate exemplary images of an apple using the above process.

FIG. 7A is an image of a slice of the apple at it's very top. 59 mm from the bottom. FIG. 7B is an image of an apple computed at 30.5 mm up from the detector, and FIG. 7C is a view of the apple computed at 13.5 mm from the bottom.

The dynamic imaging software reconstructs three-dimensional images (tomosynthesis) from two-dimensional projection images in real-time and on-demand. The software offers the ability to examine any slice depth, tilt the reconstruction plane for multiplanar views and gives higher resolution magnifications (FIG. 7). Real-time image reconstruction enables immediate review, higher throughput, and more efficient interventional procedures reducing patient call backs and data storage needs. Multiplanar reconstruction enables reconstruction to any depth, magnification and plane, giving the viewer the greater ability to view and interrogate image data, thereby reducing the likelihood of missing small structures. Built-in filters allow higher in-plane resolution and image quality during magnification for greater diagnostic confidence. Software is optimized for performance using GPU technology.

The reconstruction software provides the users greater flexibility and improved visibility of the image data. It reconstructs images at any depth specified by the user rather than at fixed slice increments. With fixed slice increments, an object located between two reconstructed slices, such as a calcification, is blurred and can be potentially missed. The software can position the reconstruction plane so that any object is exactly in focus. This includes objects that are oriented at an angle to the detector; in the software the reconstruction plane can be angled with respect to the detector plane.

Another embodiment of a system incorporating aspects of the present disclosure is illustrated in FIG. 8. FIG. 8 schematically illustrates the orientation of the mechanism as seen when the door is opened and the mechanism is located at approximately 0° 14, similar to FIG. 2. Motion of the source 10 will generally occur from the back to the front with the detector 20 orientated at the base of the cabinet chamber 22. The reference “C” refers to the point source of the X-ray beam. The reference “M” refers to the spread or fan of the X-ray. Illustration is provided when the sample is elevated above the detector on the magnification tray 30 to affect geometric magnification. Geometric magnification is achieved by moving the movable magnification tray 30 closer to the x-ray source 10 brackets on which the magnification tray 30 is supported, the brackets being to mounted (permanently or temporarily) to the sides (interior walls) of the cabinet at different distances from the detector 20. In this example, brackets 32 could produce a 2× magnification of sample 18 when magnification tray 30 with sample 18 is positioned on brackets 32 and brackets 34 could produce a 1.5× magnification of sample 18 when magnification tray 30 with sample 18 is positioned on brackets 34. However, these are exemplified magnification powers and shelf bracket heights and are not to be considered limiting. If we affix shelf bracket 32 and the magnification tray 30 closer to the x-ray source 10 we will attain a greater geometric magnification—3× or more. The magnification tray 30 is normally kept outside the x-ray chamber 28, for example, when sample 18 is positioned on detector 20, as illustrated, for example, in FIG. 1. and is constructed of a radio translucent (x-ray transparent) material such as plastic or carbon fibre.

FIG. 9 schematically displays items as described in FIG. 1 but the difference is that the sample is raised above the detector to effect geometric magnification with distance above the detector 19 illustrated

FIG. 10A, 10B and 10C illustrate geometric magnification. Geometric magnification results from the detector being farther away from the X-ray source than the object. In this regard, the source-detector distance or SDD 510 (also called the source to image-receptor distance or SID) is a measurement of the distance between the x-ray tube 10 and the detector 20.

The estimated radiographic magnification factor (ERMF) is the ratio of the source-detector distance 510 (SDD) over the source-object distance 512 (SOD).

The source-detector distance 510 (SDD) is roughly related to the source-object distance 512 (SOD) and the object-detector distance 514 (ODD) by the equation SOD 512+ODD 514=SDD 510.

Similar to a lens in photography, where the sample 18 is positioned relative to the source 10 and detector 20 changes magnification and field of view. Three terms are used to describe positioning: source-object distance 512 (SOD, where the object represents the sample); object-image distance 514 (OID, where the image is the detector 20); and source-image distance (SID) or source detector distance 510 (SDD). The effects of moving the sample 18 and detector 20 can be seen by the method of similar triangles. In the example as shown in FIGS. 10A, 10B and 10C as the top triangles 512A, 512B and 512C (cross hatch fill) get shorter going from FIG. 10A to FIG. 10B to FIG. 10C, the bottom triangles 514A, 514B and 514C (checker fill) get longer and the base of the triangles 526A, 526B and 526C gets wider effecting magnification on the detector 20 and the magnification of the resulting images 520, 522 and 524.

In FIG. 10B the sample 18 is moved away from the source 10 and the resultant image 520, 522, 524 goes down in size (less magnified) as the sample 18 moves closer to the detector 20. Differences in magnification are exhibited by the differing triangle lengths and the resultant image which represent the source-object distance 512 (SOD) and the object-detector distance 514 (ODD). Preferably for geometric magnification, the sample 18 is supported by a magnification tray 30 (in FIGS. 8 and 9) to be imaged.

Thus, while there have been shown and described and pointed out fundamental novel features of the invention as applied to the exemplary embodiments thereof, it will be understood that various omissions and substitutions and changes in the form and details of devices illustrated, and in their operation, may be made by those skilled in the art without departing from the spirit of the invention. For example, it is expressly intended that all combinations of those elements and/or method steps which perform substantially the same function in substantially the same way to achieve the same results are within the scope of the invention. Moreover, it should be recognized that structures and/or elements and/or method steps shown and/or described in connection with any disclosed form or embodiment of the invention may be incorporated in any other disclosed or described or suggested form or embodiment as a general matter of design choice. It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto. 

The invention claimed is:
 1. A cabinet x-ray system for of obtaining geometric magnifying specimen x-ray images, projection x-ray images, and reconstructed tomosynthetic x-ray images of the specimen, the system comprising: a cabinet defining a walled enclosure surrounding an interior chamber and a door configured to cover the interior chamber; an x-ray source, an x-ray detector, a specimen platform including a magnification tray that is positioned at a distance above the x-ray detector to facilitate geometric magnification imaging of the specimen in the cabinet and a motion control mechanism configured for moving the x-ray source to or along a plurality of positions within the interior chamber relative to the specimen disposed on the specimen platform; a controller configured to: a) selectively energize the x-ray source to emit x-rays through the specimen to the x-ray detector at selected positions of the x-ray source relative to the specimen such that the isocenter of the emitted x-rays at the selected positions is located at the x-ray detector surface, wherein the controller is configured to: b) control the x-ray detector to collect projection x-ray images of the specimen when the x-ray source is energized at the selected positions, wherein one of the projection x-ray images is a two-dimensional x-ray image taken at standard imaging angle of about 0°; c) create a tomosynthetic x-ray image reconstructed from a collection of projection x-ray images; d) process the collection of the projection x-ray images in the controller into one or more reconstructed tomosynthetic x-ray images representing a volume of the specimen and relating to one or more image planes that are selectively the same or different from that of the two-dimensional x-ray image; and e) selectively display the two-dimensional x-ray image and the one or more reconstructed tomosynthetic x-ray images.
 2. The cabinet x-ray system of claim 1, wherein the cabinet comprises a sampling chamber within the interior chamber for containing the specimen.
 3. The cabinet x-ray system of claim 1, wherein the specimen platform is configured for excised tissue, organ or bone specimens.
 4. The cabinet x-ray system of claim 1, wherein the specimen platform is capable of being positioned within the chamber at a plurality of distances above the x-ray detector to facilitate geometric magnification imaging of the specimen.
 5. The cabinet x-ray system of claim 1, wherein the magnification tray is a non-metallic, radio-translucent material.
 6. The cabinet x-ray system of claim 1, further comprising an x-ray cabinet wherein the specimen platform is configured for any organic or inorganic specimen that fits inside the x-ray cabinet.
 7. The cabinet x-ray system of claim 1, wherein the controller is mounted in the cabinet.
 8. The cabinet x-ray system of claim 1, wherein the x-ray source is a moveable x-ray source, the cabinet x-ray system including a device to move or position the x-ray source within the cabinet.
 9. The cabinet x-ray system of claim 1, wherein the motion control mechanism is configured to move the x-ray source along a path substantially defining an arc.
 10. The cabinet x-ray system of claim 1, wherein the x-ray detector is in a stationary or fixed position within the cabinet.
 11. The cabinet x-ray system of claim 1, wherein the motion control mechanism is configured to move the x-ray source along a path in a range from about 350° to 10° or from about 340° to 20° or vice versa or a maximum of about 335° to 25° or vice versa.
 12. The cabinet x-ray system of claim 1, wherein the motion control mechanism is configured to move the x-ray source from back to front or front to back in the cabinet.
 13. The cabinet x-ray system of claim 1, wherein the movement of the x-ray within the cabinet source is from side to side such that the spread of the x-ray beam along the path is within the spread of the x-ray beam when the x-ray source is at the standard imaging angle of about 0°.
 14. The cabinet x-ray system of claim 1, in which the x-ray source is a minimum 50 kVp and 1000 μa X-ray source.
 15. The cabinet x-ray system of claim 1, in which the x-ray source is a micro-focus X-ray source.
 16. The cabinet x-ray system of claim 1, in which the x-ray detector comprises a CMOS x-ray detector.
 17. The cabinet x-ray system of claim 1, in which the controller is configured to supply standard two-dimensional x-ray images.
 18. The cabinet x-ray system of claim 1, in which the controller is configured to interpolate the projection x-ray images gathered and calculate a tomosynthetic x-ray image.
 19. The cabinet x-ray system of claim 1, wherein the controller comprises one or more processors and computer readable program code or non-transitory machine readable instructions, which when executed by the one or more processors of the controller, is configured to provide built-in filters allowing higher in-plane resolution and image quality of the one or more reconstructed tomosynthetic x-ray images during magnification for greater diagnostic confidence.
 20. The cabinet x-ray system of claim 1, wherein the controller is configured to reconstruct three-dimensional tomosynthetic x-ray images from two-dimensional projection x-ray images in real-time and on-demand.
 21. The cabinet x-ray system of claim 1, wherein the controller includes graphic processor unit (GPU) technology and is configured to deliver real-time three-dimensional image reconstruction of tomosynthetic x-ray images by utilizing graphic processor unit (GPU) technology.
 22. The cabinet x-ray system of claim 1, wherein the specimen platform is configured for a breast specimen of a person.
 23. The cabinet x-ray system of claim 1, in which the cabinet is a moveable cabinet.
 24. The cabinet x-ray system of claim 1, in which the x-ray detector is a digital x-ray detector.
 25. The cabinet x-ray system of claim 24, in which the digital x-ray detector is a flat panel digital x-ray detector. 